Chapter 5. OpenShift Data Foundation deployed using local storage devices

5.1. Replacing operational or failed storage devices on clusters backed by local storage devices

You can replace an object storage device (OSD) in OpenShift Data Foundation deployed using local storage devices on the following infrastructures:

  • Bare metal
  • VMware
  • Red Hat Virtualization
Note

One or more underlying storage devices may need to be replaced.

Prerequisites

  • Red Hat recommends that replacement devices are configured with similar infrastructure and resources to the device being replaced.
  • If you upgraded to OpenShift Data Foundation version 4.9 from a previous version, and have not already created the LocalVolumeDiscovery and LocalVolumeSet objects, follow the procedure described in Post-update configuration changes for clusters backed by local storage.
  • Ensure that the data is resilient.

    • In the OpenShift Web Console, click StorageOpenShift Data Foundation.
    • Click the Storage Systems tab, and then click ocs-storagecluster-storagesystem.
    • In the Status card of Block and File dashboard, under the Overview tab, verify that Data Resiliency has a green tick mark.

Procedure

  1. Remove the underlying storage device from relevant worker node.
  2. Verify that relevant OSD Pod has moved to CrashLoopBackOff state.

    Identify the OSD that needs to be replaced and the OpenShift Container Platform node that has the OSD scheduled on it.

    $ oc get -n openshift-storage pods -l app=rook-ceph-osd -o wide

    Example output:

    rook-ceph-osd-0-6d77d6c7c6-m8xj6    0/1    CrashLoopBackOff    0    24h   10.129.0.16   compute-2   <none>           <none>
    rook-ceph-osd-1-85d99fb95f-2svc7    1/1    Running             0    24h   10.128.2.24   compute-0   <none>           <none>
    rook-ceph-osd-2-6c66cdb977-jp542    1/1    Running             0    24h   10.130.0.18   compute-1   <none>           <none>

    In this example, rook-ceph-osd-0-6d77d6c7c6-m8xj6 needs to be replaced and compute-2 is the OpenShift Container platform node on which the OSD is scheduled.

  3. Scale down the OSD deployment for the OSD to be replaced.

    $ osd_id_to_remove=0
    $ oc scale -n openshift-storage deployment rook-ceph-osd-${osd_id_to_remove} --replicas=0

    where, osd_id_to_remove is the integer in the pod name immediately after the rook-ceph-osd prefix. In this example, the deployment name is rook-ceph-osd-0.

    Example output:

    deployment.extensions/rook-ceph-osd-0 scaled
  4. Verify that the rook-ceph-osd pod is terminated.

    $ oc get -n openshift-storage pods -l ceph-osd-id=${osd_id_to_remove}

    Example output:

    No resources found in openshift-storage namespace.
    Important

    If the rook-ceph-osd pod is in terminating state for more than a few minutes, use the force option to delete the pod.

    $ oc delete -n openshift-storage pod rook-ceph-osd-0-6d77d6c7c6-m8xj6 --grace-period=0 --force

    Example output:

    warning: Immediate deletion does not wait for confirmation that the running resource has been terminated. The resource may continue to run on the cluster indefinitely.
      pod "rook-ceph-osd-0-6d77d6c7c6-m8xj6" force deleted
  5. Remove the old OSD from the cluster so that you can add a new OSD.

    1. Delete any old ocs-osd-removal jobs.

      $ oc delete -n openshift-storage job ocs-osd-removal-job

      Example output:

      job.batch "ocs-osd-removal-job" deleted
    2. Navigate to the openshift-storage project.

      $ oc project openshift-storage
    3. Remove the old OSD from the cluster.

      $ oc process -n openshift-storage ocs-osd-removal \
      -p FAILED_OSD_IDS=<failed_osd_id> FORCE_OSD_REMOVAL=false | oc create -n openshift-storage -f -
      <failed_osd_id>

      Is the integer in the pod name immediately after the rook-ceph-osd prefix. You can add comma separated OSD IDs in the command to remove more than one OSD, for example, FAILED_OSD_IDS=0,1,2.

      The FORCE_OSD_REMOVAL value must be changed to true in clusters that only have three OSDs, or clusters with insufficient space to restore all three replicas of the data after the OSD is removed.

      Warning

      This step results in OSD being completely removed from the cluster. Ensure that the correct value of osd_id_to_remove is provided.

  6. Verify that the OSD was removed successfully by checking the status of the ocs-osd-removal-job pod.

    A status of Completed confirms that the OSD removal job succeeded.

    # oc get pod -l job-name=ocs-osd-removal-job -n openshift-storage
  7. Ensure that the OSD removal is completed.

    $ oc logs -l job-name=ocs-osd-removal-job -n openshift-storage --tail=-1 | egrep -i 'completed removal'

    Example output:

    2022-05-10 06:50:04.501511 I | cephosd: completed removal of OSD 0
    Important

    If the ocs-osd-removal-job fails and the pod is not in the expected Completed state, check the pod logs for further debugging.

    For example:

    # oc logs -l job-name=ocs-osd-removal-job -n openshift-storage --tail=-1
  8. If encryption was enabled at the time of install, remove dm-crypt managed device-mapper mapping from the OSD devices that are removed from the respective OpenShift Data Foundation nodes.

    1. Get the Persistent Volume Claim (PVC) name(s) of the replaced OSD(s) from the logs of ocs-osd-removal-job pod.

      $ oc logs -l job-name=ocs-osd-removal-job -n openshift-storage --tail=-1  |egrep -i ‘pvc|deviceset’

      Example output:

      2021-05-12 14:31:34.666000 I | cephosd: removing the OSD PVC "ocs-deviceset-xxxx-xxx-xxx-xxx"
    2. For each of the previously identified nodes, do the following:

      1. Create a debug pod and chroot to the host on the storage node.

        $ oc debug node/<node name>
        <node name>

        Is the name of the node.

        $ chroot /host
      2. Find the relevant device name based on the PVC names identified in the previous step.

        $ dmsetup ls| grep <pvc name>
        <pvc name>

        Is the name of the PVC.

        Example output:

        ocs-deviceset-xxx-xxx-xxx-xxx-block-dmcrypt (253:0)
      3. Remove the mapped device.

        $ cryptsetup luksClose --debug --verbose ocs-deviceset-xxx-xxx-xxx-xxx-block-dmcrypt
        Important

        If the above command gets stuck due to insufficient privileges, run the following commands:

        • Press CTRL+Z to exit the above command.
        • Find the PID of the process which was stuck.

          $ ps -ef | grep crypt
        • Terminate the process using the kill command.

          $ kill -9 <PID>
          <PID>
          Is the process ID.
        • Verify that the device name is removed.

          $ dmsetup ls
  9. Find the persistent volume (PV) that need to be deleted.

    $ oc get pv -L kubernetes.io/hostname | grep localblock | grep Released

    Example output:

    local-pv-d6bf175b           1490Gi       RWO         Delete          Released            openshift-storage/ocs-deviceset-0-data-0-6c5pw      localblock      2d22h       compute-1
  10. Delete the PV.

    $ oc delete pv <pv_name>
  1. Physically add a new device to the node.
  2. Track the provisioning of PVs for the devices that match the deviceInclusionSpec. It can take a few minutes to provision the PVs.

    $ oc -n openshift-local-storage describe localvolumeset localblock

    Example output:

    [...]
    Status:
      Conditions:
        Last Transition Time:          2020-11-17T05:03:32Z
        Message:                       DiskMaker: Available, LocalProvisioner: Available
        Status:                        True
        Type:                          DaemonSetsAvailable
        Last Transition Time:          2020-11-17T05:03:34Z
        Message:                       Operator reconciled successfully.
        Status:                        True
        Type:                          Available
      Observed Generation:             1
      Total Provisioned Device Count: 4
    Events:
    Type    Reason      Age          From                Message
    ----    ------      ----         ----                -------
    Normal  Discovered  2m30s (x4    localvolumeset-     node.example.com -
            NewDevice   over 2m30s)  symlink-controller  found possible
                                                         matching disk,
                                                         waiting 1m to claim
    
    Normal  FoundMatch  89s (x4      localvolumeset-     node.example.com -
            ingDisk     over 89s)    symlink-controller  symlinking matching
                                                         disk

    Once the PV is provisioned, a new OSD pod is automatically created for the PV.

  3. Delete the ocs-osd-removal job(s).

    $ oc delete -n openshift-storage job ocs-osd-removal-job

    Example output:

    job.batch "ocs-osd-removal-job" deleted
Note

When using an external key management system (KMS) with data encryption, the old OSD encryption key can be removed from the Vault server as it is now an orphan key.

Verification steps

  1. Verify that there is a new OSD running.

    $ oc get -n openshift-storage pods -l app=rook-ceph-osd

    Example output:

    rook-ceph-osd-0-5f7f4747d4-snshw    1/1     Running     0          4m47s
    rook-ceph-osd-1-85d99fb95f-2svc7    1/1     Running     0          1d20h
    rook-ceph-osd-2-6c66cdb977-jp542    1/1     Running     0          1d20h
    Important

    If the new OSD does not show as Running after a few minutes, restart the rook-ceph-operator pod to force a reconciliation.

    $ oc delete pod -n openshift-storage -l app=rook-ceph-operator

    Example output:

    pod "rook-ceph-operator-6f74fb5bff-2d982" deleted
  2. Verify that a new PVC is created.

    $ oc get -n openshift-storage pvc | grep localblock

    Example output:

    ocs-deviceset-0-0-c2mqb   Bound    local-pv-b481410         1490Gi     RWO            localblock                    5m
    ocs-deviceset-1-0-959rp   Bound    local-pv-414755e0        1490Gi     RWO            localblock                    1d20h
    ocs-deviceset-2-0-79j94   Bound    local-pv-3e8964d3        1490Gi     RWO            localblock                    1d20h
  3. Optional: If cluster-wide encryption is enabled on the cluster, verify that the new OSD devices are encrypted.

    1. Identify the node(s) where the new OSD pod(s) are running.

      $ oc get -o=custom-columns=NODE:.spec.nodeName pod/<OSD pod name>
      <OSD pod name>

      Is the name of the OSD pod.

      For example:

      oc get -o=custom-columns=NODE:.spec.nodeName pod/rook-ceph-osd-0-544db49d7f-qrgqm
    2. For each of the nodes identified in the previous step, do the following:

      1. Create a debug pod and open a chroot environment for the selected host(s).

        $ oc debug node/<node name>
        <node name>

        Is the name of the node.

        $ chroot /host
      2. Check for the crypt keyword beside the ocs-deviceset name(s).

        $ lsblk
  4. Log in to OpenShift Web Console and check the OSD status on the storage dashboard.
Note

A full data recovery may take longer depending on the volume of data being recovered.

5.2. Replacing operational or failed storage devices on IBM Power

You can replace an object storage device (OSD) in OpenShift Data Foundation deployed using local storage devices on IBM Power.

Note

One or more underlying storage devices may need to be replaced.

Prerequisites

  • Red Hat recommends that replacement devices are configured with similar infrastructure and resources to the deice being replaced.
  • If you upgraded to OpenShift Data Foundation version 4.9 from a previous version and have not already created the LocalVolumeDiscovery object, follow the procedure described in Post-update configuration changes for clusters backed by local storage.
  • Ensure that the data is resilient.

    • In the OpenShift Web Console, click StorageOpenShift Data Foundation.
    • Click the Storage Systems tab, and then click ocs-storagecluster-storagesystem.
    • In the Status card of Block and File dashboard, under the Overview tab, verify that Data Resiliency has a green tick mark.

Procedure

  1. Identify the OSD that needs to be replaced and the OpenShift Container Platform node that has the OSD scheduled on it.

    $ oc get -n openshift-storage pods -l app=rook-ceph-osd -o wide

    Example output:

    rook-ceph-osd-0-86bf8cdc8-4nb5t   0/1     crashLoopBackOff   0   24h   10.129.2.26     worker-0     <none>       <none>
    rook-ceph-osd-1-7c99657cfb-jdzvz   1/1     Running   0          24h     10.128.2.46     worker-1     <none>       <none>
    rook-ceph-osd-2-5f9f6dfb5b-2mnw9    1/1     Running   0          24h     10.131.0.33    worker-2     <none>       <none>

    In this example, rook-ceph-osd-0-86bf8cdc8-4nb5t needs to be replaced and worker-0 is the RHOCP node on which the OSD is scheduled.

    Note

    If the OSD to be replaced is healthy, the status of the pod will be Running.

  2. Scale down the OSD deployment for the OSD to be replaced.

    $ osd_id_to_remove=0
    $ oc scale -n openshift-storage deployment rook-ceph-osd-${osd_id_to_remove} --replicas=0

    where, osd_id_to_remove is the integer in the pod name immediately after the rook-ceph-osd prefix. In this example, the deployment name is rook-ceph-osd-0.

    Example output:

    deployment.extensions/rook-ceph-osd-0 scaled
  3. Verify that the rook-ceph-osd pod is terminated.

    $ oc get -n openshift-storage pods -l ceph-osd-id=${osd_id_to_remove}

    Example output:

    No resources found in openshift-storage namespace.
    Important

    If the rook-ceph-osd pod is in terminating state for more than a few minutes, use the force option to delete the pod.

    $ oc delete -n openshift-storage pod rook-ceph-osd-0-86bf8cdc8-4nb5t --grace-period=0 --force

    Example output:

    warning: Immediate deletion does not wait for confirmation that the running resource has been terminated. The resource may continue to run on the cluster indefinitely.
      pod "rook-ceph-osd-0-86bf8cdc8-4nb5t" force deleted
  4. Remove the old OSD from the cluster so that you can add a new OSD.

    1. Identify the DeviceSet associated with the OSD to be replaced.

      $ oc get -n openshift-storage -o yaml deployment rook-ceph-osd-${osd_id_to_remove} | grep ceph.rook.io/pvc

      Example output:

      ceph.rook.io/pvc: ocs-deviceset-localblock-0-data-0-64xjl
          ceph.rook.io/pvc: ocs-deviceset-localblock-0-data-0-64xjl

      In this example, the Persistent Volume Claim (PVC) name is ocs-deviceset-localblock-0-data-0-64xjl.

    2. Identify the Persistent Volume (PV) associated with the PVC.

      $ oc get -n openshift-storage pvc ocs-deviceset-<x>-<y>-<pvc-suffix>

      where, x, y, and pvc-suffix are the values in the DeviceSet identified in an earlier step.

      Example output:

      NAME                      STATUS        VOLUME        CAPACITY   ACCESS MODES   STORAGECLASS   AGE
      ocs-deviceset-localblock-0-data-0-64xjl   Bound    local-pv-8137c873    256Gi      RWO     localblock     24h

      In this example, the associated PV is local-pv-8137c873.

    3. Identify the name of the device to be replaced.

      $ oc get pv local-pv-<pv-suffix> -o yaml | grep path

      where, pv-suffix is the value in the PV name identified in an earlier step.

      Example output:

      path: /mnt/local-storage/localblock/vdc

      In this example, the device name is vdc.

    4. Identify the prepare-pod associated with the OSD to be replaced.

      $ oc describe -n openshift-storage pvc ocs-deviceset-<x>-<y>-<pvc-suffix> | grep Used

      where, x, y, and pvc-suffix are the values in the DeviceSet identified in an earlier step.

      Example output:

      Used By:    rook-ceph-osd-prepare-ocs-deviceset-localblock-0-data-0-64knzkc

      In this example, the prepare-pod name is rook-ceph-osd-prepare-ocs-deviceset-localblock-0-data-0-64knzkc.

    5. Delete any old ocs-osd-removal jobs.

      $ oc delete -n openshift-storage job ocs-osd-removal-job

      Example output:

      job.batch "ocs-osd-removal-job" deleted
    6. Change to the openshift-storage project.

      $ oc project openshift-storage
    7. Remove the old OSD from the cluster.

      $ oc process -n openshift-storage ocs-osd-removal \
      -p FAILED_OSD_IDS=<failed_osd_id> FORCE_OSD_REMOVAL=false | oc create -n openshift-storage -f -
      <failed_osd_id>

      Is the integer in the pod name immediately after the rook-ceph-osd prefix. You can add comma separated OSD IDs in the command to remove more than one OSD, for example, FAILED_OSD_IDS=0,1,2.

      The FORCE_OSD_REMOVAL value must be changed to true in clusters that only have three OSDs, or clusters with insufficient space to restore all three replicas of the data after the OSD is removed.

      Warning

      This step results in OSD being completely removed from the cluster. Ensure that the correct value of osd_id_to_remove is provided.

  5. Verify that the OSD was removed successfully by checking the status of the ocs-osd-removal-job pod.

    A status of Completed confirms that the OSD removal job succeeded.

    # oc get pod -l job-name=ocs-osd-removal-job -n openshift-storage
  6. Ensure that the OSD removal is completed.

    $ oc logs -l job-name=ocs-osd-removal-job -n openshift-storage --tail=-1 | egrep -i 'completed removal'

    Example output:

    2022-05-10 06:50:04.501511 I | cephosd: completed removal of OSD 0
    Important

    If the ocs-osd-removal-job fails and the pod is not in the expected Completed state, check the pod logs for further debugging.

    For example:

    # oc logs -l job-name=ocs-osd-removal-job -n openshift-storage --tail=-1
  7. If encryption was enabled at the time of install, remove dm-crypt managed device-mapper mapping from the OSD devices that are removed from the respective OpenShift Data Foundation nodes.

    1. Get the PVC name(s) of the replaced OSD(s) from the logs of ocs-osd-removal-job pod.

      $ oc logs -l job-name=ocs-osd-removal-job -n openshift-storage --tail=-1  |egrep -i ‘pvc|deviceset’

      Example output:

      2021-05-12 14:31:34.666000 I | cephosd: removing the OSD PVC "ocs-deviceset-xxxx-xxx-xxx-xxx"
    2. For each of the previously identified nodes, do the following:

      1. Create a debug pod and chroot to the host on the storage node.

        $ oc debug node/<node name>
        <node name>

        Is the name of the node.

        $ chroot /host
      2. Find the relevant device name based on the PVC names identified in the previous step.

        $ dmsetup ls| grep <pvc name>
        <pvc name>

        Is the name of the PVC.

        Example output:

        ocs-deviceset-xxx-xxx-xxx-xxx-block-dmcrypt (253:0)
      3. Remove the mapped device.

        $ cryptsetup luksClose --debug --verbose ocs-deviceset-xxx-xxx-xxx-xxx-block-dmcrypt
        Important

        If the above command gets stuck due to insufficient privileges, run the following commands:

        • Press CTRL+Z to exit the above command.
        • Find the PID of the process which was stuck.

          $ ps -ef | grep crypt
        • Terminate the process using the kill command.

          $ kill -9 <PID>
          <PID>
          Is the process ID.
        • Verify that the device name is removed.

          $ dmsetup ls
  8. Find the PV that need to be deleted.

    $ oc get pv -L kubernetes.io/hostname | grep localblock | grep Released

    Example output:

    local-pv-d6bf175b           1490Gi       RWO         Delete          Released            openshift-storage/ocs-deviceset-0-data-0-6c5pw      localblock      2d22h       compute-1
  9. Delete the PV.

    $ oc delete pv <pv-name>
    <pv-name>
    Is the name of the PV.
  10. Replace the old device and use the new device to create a new OpenShift Container Platform PV.

    1. Log in to the OpenShift Container Platform node with the device to be replaced. In this example, the OpenShift Container Platform node is worker-0.

      $ oc debug node/worker-0

      Example output:

      Starting pod/worker-0-debug ...
      To use host binaries, run `chroot /host`
      Pod IP: 192.168.88.21
      If you don't see a command prompt, try pressing enter.
      # chroot /host
    2. Record the /dev/disk that is to be replaced using the device name, vdc, identified earlier.

      # ls -alh /mnt/local-storage/localblock

      Example output:

      total 0
      drwxr-xr-x. 2 root root 17 Nov  18 15:23 .
      drwxr-xr-x. 3 root root 24 Nov  18 15:23 ..
      lrwxrwxrwx. 1 root root  8 Nov  18 15:23 vdc -> /dev/vdc
    3. Find the name of the LocalVolume CR, and remove or comment out the device /dev/disk that is to be replaced.

      $ oc get -n openshift-local-storage localvolume

      Example output:

      NAME          AGE
      localblock   25h
      # oc edit -n openshift-local-storage localvolume localblock

      Example output:

      [...]
          storageClassDevices:
          - devicePaths:
         #   - /dev/vdc
            storageClassName: localblock
            volumeMode: Block
      [...]

      Make sure to save the changes after editing the CR.

  11. Log in to the OpenShift Container Platform node with the device to be replaced and remove the old symlink.

    $ oc debug node/worker-0

    Example output:

    Starting pod/worker-0-debug ...
    To use host binaries, run `chroot /host`
    Pod IP: 192.168.88.21
    If you don't see a command prompt, try pressing enter.
    # chroot /host
    1. Identify the old symlink for the device name to be replaced. In this example, the device name is vdc.

      # ls -alh /mnt/local-storage/localblock

      Example output:

      total 0
      drwxr-xr-x. 2 root root 17 Nov  18 15:23 .
      drwxr-xr-x. 3 root root 24 Nov  18 15:23 ..
      lrwxrwxrwx. 1 root root  8 Nov  18 15:23 vdc -> /dev/vdc
    2. Remove the symlink.

      # rm /mnt/local-storage/localblock/vdc
    3. Verify that the symlink is removed.

      # ls -alh /mnt/local-storage/localblock

      Example output:

      total 0
      drwxr-xr-x. 2 root root 6 Nov 18 17:11 .
      drwxr-xr-x. 3 root root 24 Nov 18 15:23 ..
  12. Replace the old device with the new device.
  13. Log back into the correct OpenShift Cotainer Platform node and identify the device name for the new drive. The device name must change unless you are resetting the same device.

    # lsblk

    Example output:

    NAME                         MAJ:MIN RM   SIZE RO TYPE MOUNTPOINT
    vda                          252:0    0   40G  0 disk
    |-vda1                       252:1    0    4M  0 part
    |-vda2                       252:2    0  384M  0 part /boot
    `-vda4                       252:4    0 39.6G  0 part
      `-coreos-luks-root-nocrypt 253:0    0 39.6G  0 dm   /sysroot
    vdb                          252:16   0  512B  1 disk
    vdd                          252:32   0  256G  0 disk

    In this example, the new device name is vdd.

  14. After the new /dev/disk is available, you can add a new disk entry to the LocalVolume CR.

    1. Edit the LocalVolume CR and add the new /dev/disk.

      In this example, the new device is /dev/vdd.

      # oc edit -n openshift-local-storage localvolume localblock

      Example output:

      [...]
          storageClassDevices:
          - devicePaths:
          #  - /dev/vdc
            - /dev/vdd
            storageClassName: localblock
            volumeMode: Block
      [...]

      Make sure to save the changes after editing the CR.

  15. Verify that there is a new PV in Available state and of the correct size.

    $ oc get pv | grep 256Gi

    Example output:

    local-pv-1e31f771   256Gi   RWO    Delete  Bound  openshift-storage/ocs-deviceset-localblock-2-data-0-6xhkf   localblock    24h
    local-pv-ec7f2b80   256Gi   RWO    Delete  Bound  openshift-storage/ocs-deviceset-localblock-1-data-0-hr2fx   localblock    24h
    local-pv-8137c873   256Gi   RWO    Delete  Available                                                          localblock    32m
  16. Create a new OSD for the new device.

    Deploy the new OSD. You need to restart the rook-ceph-operator to force operator reconciliation.

    1. Identify the name of the rook-ceph-operator.

      $ oc get -n openshift-storage pod -l app=rook-ceph-operator

      Example output:

      NAME                                  READY   STATUS    RESTARTS   AGE
      rook-ceph-operator-85f6494db4-sg62v   1/1     Running   0          1d20h
    2. Delete the rook-ceph-operator.

      $ oc delete -n openshift-storage pod rook-ceph-operator-85f6494db4-sg62v

      Example output:

      pod "rook-ceph-operator-85f6494db4-sg62v" deleted

      In this example, the rook-ceph-operator pod name is rook-ceph-operator-85f6494db4-sg62v.

    3. Verify that the rook-ceph-operator pod is restarted.

      $ oc get -n openshift-storage pod -l app=rook-ceph-operator

      Example output:

      NAME                                  READY   STATUS    RESTARTS   AGE
      rook-ceph-operator-85f6494db4-wx9xx   1/1     Running   0          50s

      Creation of the new OSD may take several minutes after the operator restarts.

  17. Delete the ocs-osd-removal job(s).

    $ oc delete -n openshift-storage job ocs-osd-removal-job

    Example output:

    job.batch "ocs-osd-removal-job" deleted
Note

When using an external key management system (KMS) with data encryption, the old OSD encryption key can be removed from the Vault server as it is now an orphan key.

Verfication steps

  1. Verify that there is a new OSD running.

    $ oc get -n openshift-storage pods -l app=rook-ceph-osd

    Example output:

    rook-ceph-osd-0-76d8fb97f9-mn8qz   1/1     Running   0          23m
    rook-ceph-osd-1-7c99657cfb-jdzvz   1/1     Running   1          25h
    rook-ceph-osd-2-5f9f6dfb5b-2mnw9   1/1     Running   0          25h
  2. Verify that a new PVC is created.

    $ oc get -n openshift-storage pvc | grep localblock

    Example output:

    ocs-deviceset-localblock-0-data-0-q4q6b   Bound    local-pv-8137c873       256Gi     RWO         localblock         10m
    ocs-deviceset-localblock-1-data-0-hr2fx   Bound    local-pv-ec7f2b80       256Gi     RWO         localblock         1d20h
    ocs-deviceset-localblock-2-data-0-6xhkf   Bound    local-pv-1e31f771       256Gi     RWO         localblock         1d20h
  3. Optional: If cluster-wide encryption is enabled on the cluster, verify that the new OSD devices are encrypted.

    1. Identify the node(s) where the new OSD pod(s) are running.

      $ oc get -o=custom-columns=NODE:.spec.nodeName pod/<OSD pod name>
      <OSD pod name>

      Is the name of the OSD pod.

      For example:

      oc get -o=custom-columns=NODE:.spec.nodeName pod/rook-ceph-osd-0-544db49d7f-qrgqm
    2. For each of the previously identified nodes, do the following:

      1. Create a debug pod and open a chroot environment for the selected host(s).

        $ oc debug node/<node name>
        <node name>

        Is the name of the node.

        $ chroot /host
      2. Check for the crypt keyword beside the ocs-deviceset name(s).

        $ lsblk
  4. Log in to OpenShift Web Console and check the status card in the Openshift Data Foundation dashboard under Storage section.
Note

A full data recovery may take longer depending on the volume of data being recovered.

5.3. Replacing operational or failed storage devices on IBM Z or LinuxONE infrastructure

You can replace operational or failed storage devices on IBM Z or LinuxONE infrastructure with new Small Computer System Interface (SCSI) disks.

IBM Z or LinuxONE supports SCSI FCP disk logical units (SCSI disks) as persistent storage devices from external disk storage. You can identify a SCSI disk using its FCP Device number, two target worldwide port names (WWPN1 and WWPN2), and the logical unit number (LUN). For more information, see https://www.ibm.com/support/knowledgecenter/SSB27U_6.4.0/com.ibm.zvm.v640.hcpa5/scsiover.html

Prerequisites

  • Ensure that the data is resilient.

    • In the OpenShift Web Console, click StorageOpenShift Data Foundation.
    • Click the Storage Systems tab, and then click ocs-storagecluster-storagesystem.
    • In the Status card of Block and File dashboard, under the Overview tab, verify that Data Resiliency has a green tick mark.

Procedure

  1. List all the disks.

    $ lszdev

    Example output:

    TYPE         ID
    zfcp-host    0.0.8204                                        yes  yes
    zfcp-lun     0.0.8204:0x102107630b1b5060:0x4001402900000000 yes  no    sda sg0
    zfcp-lun     0.0.8204:0x500407630c0b50a4:0x3002b03000000000  yes  yes   sdb sg1
    qeth         0.0.bdd0:0.0.bdd1:0.0.bdd2                      yes  no    encbdd0
    generic-ccw  0.0.0009                                        yes  no

    A SCSI disk is represented as a zfcp-lun with the structure <device-id>:<wwpn>:<lun-id> in the ID section. The first disk is used for the operating system. If one storage device fails, you can replace it with a new disk.

  2. Remove the disk.

    Run the following command on the disk, replacing scsi-id with the SCSI disk identifier of the disk to be replaced:

    $ chzdev -d scsi-id

    For example, the following command removes one disk with the device ID 0.0.8204, the WWPN 0x500507630a0b50a4, and the LUN 0x4002403000000000:

    $ chzdev -d 0.0.8204:0x500407630c0b50a4:0x3002b03000000000
  3. Append a new SCSI disk.

    $ chzdev -e 0.0.8204:0x500507630b1b50a4:0x4001302a00000000
    Note

    The device ID for the new disk must be the same as the disk to be replaced. The new disk is identified with its WWPN and LUN ID.

  4. List all the FCP devices to verify the new disk is configured.

    $ lszdev zfcp-lun

    Example output:

    TYPE         ID                                              ON   PERS  NAMES
    zfcp-lun     0.0.8204:0x102107630b1b5060:0x4001402900000000 yes  no    sda sg0
    zfcp-lun     0.0.8204:0x500507630b1b50a4:0x4001302a00000000  yes  yes   sdb sg1